An asymmetric scroll compressor includes a compressor housing. An orbiting scroll member and a non-orbiting scroll member disposed within the compressor housing. The orbiting scroll member and the non-orbiting scroll member each includes a baseplate and a wrap extending from the baseplate. The orbiting scroll member and the non-orbiting scroll member intermeshed to form a plurality of compression pockets. A driveshaft affixed to the orbiting scroll member and configured to orbit the orbiting scroll member from a first orbital position to a second orbital position. A communication port disposed on the baseplate of one of the orbiting scroll member and the non-orbiting scroll such that: in the first orbital position, the communication port communicates with a first enclosed pocket of the plurality of compression pockets, and in the second orbital position, the communication port communicates with a second enclosed pocket of the plurality of compression pockets.
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1. An asymmetric scroll compressor comprising:
a compressor housing;
an orbiting scroll member and a non-orbiting scroll member disposed within the compressor housing, the orbiting scroll member and the non-orbiting scroll member each include a baseplate and a wrap extending from the baseplate, the orbiting scroll member and the non-orbiting scroll member intermeshed to form a plurality of compression pockets;
a driveshaft coupled to the orbiting scroll member and configured to orbit the orbiting scroll member from a first orbital position to a second orbital position;
a communication port disposed in a porting envelope, the porting envelope defined by an overlapping area from relative orbital movements of a first enclosed pocket and a second enclosed pocket of the plurality of compression pockets, the communication port including an inner side having a contour matching a contour of an inner side of the porting envelope and an outer side having a contour matching a contour of an outer side of the porting envelope, the inner side and the outer side being opposite sides of the communication port, the inner side of the communication port and the inner side of the porting envelope being closer to the driveshaft than the outer side of the communication port and the outer side of the porting envelope, respectively, such that:
in the first orbital position, the communication port communicates with the first enclosed pocket of the plurality of compression pockets, and
in the second orbital position, the communication port communicates with the second enclosed pocket of the plurality of compression pockets, wherein the orbiting scroll member has an intermediate orbital position between the first orbital position and the second orbital position such that:
in the intermediate orbital position, the communication port communicates with both the first enclosed pocket and the second enclosed pocket, wherein the communication port outlet spans across the wrap of the orbiting scroll member to extend onto both the first enclosed pocket and the second enclosed pocket.
10. A refrigerant circuit, comprising:
an asymmetric scroll compressor, an expander, a condenser, and an evaporator fluidly connected, wherein the asymmetric scroll compressor includes:
a compressor housing;
an orbiting scroll member and a non-orbiting scroll member disposed within the compressor housing, the orbiting scroll member and the non-orbiting scroll member each include a baseplate and a wrap extending from the baseplate, the orbiting scroll member and the non-orbiting scroll member intermeshed to form a plurality of compression pockets;
a driveshaft affixed to the orbiting scroll member configured to orbit the orbiting scroll member from a first orbital position to a second orbital position;
a communication port including a communication port disposed in a porting envelope, the porting envelope defined by an overlapping area from relative orbital movements of a first enclosed pocket and a second enclosed pocket of the plurality of compression pockets, the communication port including an inner side having a contour matching a contour of an inner side of the porting envelope and an outer side having a contour matching a contour of an outer side of the porting envelope, the inner side and the outer side being opposite sides of the communication port, the inner side of the communication port and the inner side of the porting envelope being closer to the driveshaft than the outer side of the communication port and the outer side of the porting envelope, respectively, such that:
in the first orbital position, the communication port communicates with the first enclosed pocket of the plurality of compression pockets, and
in the second orbital position, the communication port communicates with the second enclosed pocket of the plurality of compression pockets,
wherein the orbiting scroll member has an intermediate orbital position between the first orbital position and the second orbital position such that:
in the intermediate orbital position, the communication port communicates with both the first enclosed pocket and the second enclosed pocket, wherein the communication port spans across the wrap of the orbiting scroll member to extend onto both the first enclosed pocket and the second enclosed pocket.
6. A method of communicating working fluid at an intermediate pressure with an asymmetric scroll compressor, comprising:
orbiting an orbiting scroll member affixed to a driveshaft from a first orbital position to a second orbital position to intermesh with a non-orbiting scroll member of the asymmetric scroll compressor, forming a plurality of compression pockets, and the orbiting scroll member and the non-orbiting scroll member each include a baseplate and a wrap extending from the baseplate;
receiving the working fluid at a suction pressure from a suction intake disposed between the orbiting scroll member and the non-orbiting scroll member;
enclosing the working fluid in the suction intake to obtain a first enclosed pocket of the plurality of compression pockets;
communicating the working fluid at an intermediate pressure from a communication port including a communication port disposed in a porting envelope, the porting envelope defined by an overlapping area from relative orbital movements of a first enclosed pocket and a second enclosed pocket of the plurality of compression pockets, the communication port including an inner side having a contour matching a contour of an inner side of the porting envelope and an outer side having a contour matching a contour of an outer side of the porting envelope, the inner side and the outer side being opposite sides of the communication port, the inner side of the communication port and the inner side of the porting envelope being closer to the driveshaft than the outer side of the communication port and the outer side of the porting envelope, respectively, such that:
in the first orbital position, communicating with the first enclosed pocket of the plurality of compression pockets via the communication port, and
in the second orbital position, communicating with a second enclosed pocket of the plurality of compression pockets via the communication port; and
discharging the working fluid at a discharge pressure through a discharge, wherein the orbiting scroll member has an intermediate orbital position between the first orbital position and the second orbital position such that:
in the intermediate orbital position, the communication port communicates with both the first enclosed pocket and the second enclosed pocket, wherein the communication port spans across the wrap of the orbiting scroll member to extend onto both the first enclosed pocket and the second enclosed pocket.
2. The asymmetric scroll compressor of
3. The asymmetric scroll compressor of
4. The asymmetric scroll compressor of
5. The asymmetric scroll compressor of
7. The method of
the first enclosed pocket and the second enclosed pocket are adjacent in a radial direction and separated by one of the wraps.
8. The method of
maintaining the first enclosed pocket and the second enclosed pocket at or about a same pressure at the intermediate orbital position.
9. The method of
orbiting the orbiting scroll member from a suction orbital position to the first orbital position to enclose the working fluid in the suction intake.
11. The refrigerant circuit of
the first enclosed pocket and the second enclosed pocket are adjacent in a radial direction and are separated by one of the wraps.
12. The refrigerant circuit of
the first enclosed pocket and the second enclosed pocket are at or about a same pressure during between the first orbital position and the second orbital position.
13. The refrigerant circuit of
a porous material is disposed in the communication port, the communication port is configured to transfer fluid through the porous material, and the porous material is configured to mitigate wear on a tip seal disposed on one of the wraps.
14. The refrigerant circuit of
the communication port is disposed within the baseplate of the non-orbiting scroll member.
15. The refrigerant circuit of
the compressor housing includes an intermediate pressure fluid port,
the intermediate pressure fluid port is configured to receive working fluid from an intermediate pressure fluid source, and
the communication port is configured to receive the working fluid at an intermediate pressure and inject the working fluid into the first enclosed pocket and the second enclosed pocket.
16. The refrigerant circuit of
the compressor housing includes an intermediate pressure fluid port,
the intermediate pressure fluid port is configured to discharge working fluid from both the first enclosed pocket and the second enclosed pocket, and
the communication port is configured to discharge the working fluid at an intermediate pressure.
17. The refrigerant circuit of
the communication port is configured to discharge the working fluid at the intermediate pressure to a suction inlet disposed on the compressor housing.
18. An asymmetric scroll compressor of
19. The method of
20. The refrigerant circuit of
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This disclosure generally relates to a scroll compressor. More specifically, this disclosure relates to communicating an intermediate pressure fluid with an asymmetric scroll compressor in a heating, ventilation, air conditioning, and refrigeration (“HVACR”) system.
A heating, ventilation, air conditioning, and refrigeration (“HVACR”) system generally includes a compressor, such as a scroll compressor. Scroll compressors include a pair of scroll members which orbit relative to each other to compress a working fluid. The wraps on the pair of scrolls in an asymmetric scroll compressor have different shapes, lengths, curvatures, or a combination thereof. The asymmetric scroll compressor compresses the working fluid (e.g., refrigerant, refrigerant mixture, or the like) at a lower pressure and discharges the fluid at a higher pressure.
This disclosure generally relates to a scroll compressor. More specifically, this disclosure relates to communicating an intermediate pressure fluid with an asymmetric scroll compressor in a heating, ventilation, air conditioning, and refrigeration (“HVACR”) system.
By providing a communication port shared between two adjacent compression pockets, an asymmetric scroll compressor can receive or discharge working fluid at an intermediate pressure. Injecting the working fluid at the intermediate pressure into the asymmetric scroll compressor can increase mass flow and/or efficiency of the compressor. By discharging the working fluid at the intermediate pressure and circulating the discharged working fluid back to a suction inlet of the compressor, the capacity of the compressor can be controlled while conserving the energy consumption of the compressor. Finally, by discharging working fluid at the intermediate pressure and circulating the discharged working fluid to the discharge line of the compressor, the power consumption can be controlled to the benefit of compressor efficiency.
According to one embodiment, an asymmetric scroll compressor includes a compressor housing. An orbiting scroll member and a non-orbiting scroll member disposed within the compressor housing. The orbiting scroll member and the non-orbiting scroll member each includes a baseplate and a wrap extending from the baseplate. The orbiting scroll member and the non-orbiting scroll member intermeshed to form a plurality of compression pockets. A driveshaft affixed to the orbiting scroll member and configured to orbit the orbiting scroll member from a first orbital position to a second orbital position. A communication port disposed on the baseplate of one of the orbiting scroll member and the non-orbiting scroll such that: in the first orbital position, the communication port communicates with a first enclosed pocket of the plurality of compression pockets, and in the second orbital position, the communication port communicates with a second enclosed pocket of the plurality of compression pockets.
In an embodiment, the orbiting scroll member has an intermediate orbital position between the first orbital position and the second orbital position, and during the intermediate orbital position, the communication port communicates with both the first enclosed pocket and the second enclosed pocket.
In an embodiment, the first enclosed pocket and the second enclosed pocket are adjacent in a radial direction and separated by one of the wraps.
In an embodiment, the first enclosed pocket and the second enclosed pocket are at or about a same pressure between the first orbital position and the second orbital position.
In an embodiment, the asymmetric scroll compressor includes a porous structure disposed in the communication port, the communication port configured to transfer fluid through the porous structure, and the porous structure configured to mitigate wear on a tip seal disposed on one of the wraps.
In an embodiment, the communication port is disposed within the baseplate of the non-orbiting scroll member.
According to another embodiment, a method of communicating working fluid at an intermediate pressure with an asymmetric scroll compressor. The asymmetric scroll compressor includes orbiting an orbiting scroll member affixed to a driveshaft from a first orbital position to a second orbital position to intermesh with a non-orbiting scroll member of the asymmetric scroll compressor, forming a plurality of compression pockets. The method further includes receiving the working fluid at a suction pressure from a suction intake disposed between the orbiting scroll member and the non-orbiting scroll member. The method further includes enclosing the working fluid in the suction intake to obtain a first enclosed pocket of the plurality of enclosed pocket. The method further includes communicating the working fluid at an intermediate pressure from a communication port such that: in the first orbital position, communicating with the first enclosed pocket of the plurality of compression pockets via the communication port, and in the second orbital position, communicating with a second enclosed pocket of the plurality of compression pockets via the communication port. The method further includes discharging the working fluid at a discharge pressure through a discharge outlet.
In an embodiment, the method includes communicating with both the first enclosed pocket and the second enclosed pocket via the communication port in an intermediate orbital position, the intermediate orbital position being between the first orbital position and the second orbital positon.
In an embodiment, the orbiting scroll member and the non-orbiting scroll member each includes a baseplate and a wrap extending from the baseplate, and the first enclosed pocket and the second enclosed pocket are adjacent in a radial direction and separated by one of the wraps.
In an embodiment, the method includes maintaining the first enclosed pocket and the second enclosed pocket at or about a same pressure at the intermediate orbital position.
In an embodiment, the method includes orbiting the orbital scroll member from a suction orbital position to the first orbital position to enclose the working fluid in the suction intake.
According to yet another embodiment, a refrigerant circuit. The refrigerant circuit includes a compressor, an expander, a condenser, and an evaporator fluidly connected. The compressor includes a compressor housing. An orbiting scroll member and a non-orbiting scroll member disposed within the compressor housing. The orbiting scroll member and the non-orbiting scroll member each includes a baseplate and a wrap extending from the baseplate. The orbiting scroll member and the non-orbiting scroll member intermeshed to form a plurality of compression pockets. A driveshaft affixed to the orbiting scroll member configured to orbit the orbiting scroll member from a first orbital position to a second orbital position. A communication port disposed on the baseplate of one of the orbiting scroll member and the non-orbiting scroll such that, in the first orbital position, the communication port communicates with a first enclosed pocket of the plurality of compression pockets, and, in the second orbital position, the communication port communicates with a second enclosed pocket of the plurality of compression pockets.
In an embodiment, the orbiting scroll member has an intermediate orbital position between the first orbital position and the second orbital position, and during the intermediate orbital position, the communication port communicates with both the first enclosed pocket and the second enclosed pocket.
In an embodiment, the first enclosed pocket and the second enclosed pocket are adjacent in a radial direction and are separated by one of the wraps.
In an embodiment, the first enclosed pocket and the second enclosed pocket are at or about a same pressure during between the first orbital position and the second orbital position.
In an embodiment, a porous structure disposed in the communication port, the communication port configured to transfer fluid through the porous structure, and the porous structure configured to mitigate wear on a tip seal disposed on one of the wraps.
In an embodiment, the communication port is disposed within the baseplate of the non-orbiting scroll member.
In an embodiment, the compressor housing includes an intermediate pressure fluid port, the intermediate pressure fluid port is configured to receive working fluid from an intermediate pressure fluid source, the communication port is configured to receive the working fluid at an intermediate pressure and inject the working fluid into the first enclosed pocket and the second enclosed pocket.
In an embodiment, the compressor housing includes an intermediate pressure fluid port, the intermediate pressure fluid port is configured to discharge working fluid from both the first enclosed pocket and the second enclosed pocket, the communication port is configured to discharge the working fluid at an intermediate pressure.
In an embodiment, the communication port is configured to discharge the working fluid at the intermediate pressure to a suction inlet disposed on the housing.
References are made to the accompanying drawings that form a part of this disclosure, and which illustrate embodiments in which the systems and methods described in this Specification can be practiced.
Like reference numbers represent like parts throughout.
This disclosure generally relates to a scroll compressor. More specifically, this disclosure relates to communicating intermediate pressure fluid with an asymmetric scroll compressor in a heating, ventilation, air conditioning, and refrigeration (“HVACR”) system.
It should be appreciated that the refrigerant circuit 1 is an exemplary embodiment and can be modified to include additional components or to remove components. In an embodiment, the refrigerant circuit 1 can include other components such as, but and not limited to, one or more flow control devices, economizers, receiver tanks, dryers, suction-liquid heat exchangers, or the like. In an embodiment, a refrigerant circuit 1 may be modified to have a single expander instead of two.
The refrigerant circuit 1 can be applied in a variety of systems used to control one or more environmental condition (e.g., temperature, humidity, air quality, or the like) in a space (generally referred to as a conditioned space). Examples of such systems include, but are not limited to, HVACR systems, transport climate control systems, or the like. Examples of a conditioned space include, but and not limited to, a portion of a home, building, an environmentally controlled container on a vehicle, ship, or vessel, or the like. In an embodiment, the refrigerant circuit 1 can be configured to be a cooling system (e.g., an air conditioning system) capable of operating in a cooling mode. In another embodiment, the refrigerant circuit 1 can be configured to be a heat pump system that can operate in both a cooling mode and a heating/defrost mode.
The refrigerant circuit 1 includes the compressor 10, the condenser 14, the first expander 16, the second expander 16′, and the evaporator 18 that are fluidly connected via refrigerant lines 20, 21, 22, 23, 24, 26, 28, 29 and/or 30. In an embodiment, the refrigerant lines 20, 21, 22, 23, 24, 26, 28, 29 and/or 30 may alternatively be referred to as refrigerant conduits.
The compressor 10 includes a suction inlet 12A, a discharge outlet 12B, and intermediate pressure fluid port 12C. Port 12C may be referred to as an intermediate port. In operation, the compressor 10 compresses a working fluid (e.g., a working fluid such as a refrigerant, refrigerant mixture, or the like) from a relatively lower pressure gas (e.g., suction pressure) to a relatively higher pressure gas (e.g., discharge pressure). Relatively lower pressure working fluid is suctioned or displaced into the compressor 10 through the suction inlet 12A. The working fluid is then compressed within the compressor 10 and discharged at the relatively higher pressure from the compressor 10 at the discharge outlet 12B. In an embodiment, the compressor 10 is an asymmetric scroll compressor.
The relatively higher-pressure working fluid discharged from the discharge outlet 12B of the compressor 10 is also at a relatively higher temperature. In an embodiment, the relatively higher-pressure working fluid is a gas. The relatively higher-pressure working fluid flows from the compressor 10 through refrigerant line 20 to the condenser 14. The working fluid flows through the condenser 14 and rejects heat to a first process fluid (e.g., water, air, etc.). The cooled working fluid, which is now liquid or mostly liquid, flows to the first expander 16 via the refrigerant line 22 and to the second expander 16′ via the refrigerant line 21. In an embodiment, an expander (e.g., first expander 16, second expander 16′) may be an expansion valve, expansion plate, expansion vessel, orifice, or other such types of expansion mechanisms. It is to be appreciated that an expander in an embodiment may be any type of expander used in the field of HVACR for expanding working fluid that causes the working fluid to decrease in temperature.
A first portion of the cooled working fluid flows from the condenser 14 to the first expander 16 via the refrigerant line 22. The first expander 16 allows the working fluid to expand and reduces the pressure of the working fluid to obtain working fluid a liquid form, a gaseous form, or a combination thereof. The working fluid now has a lower temperature after being expanded by the first expander 16. This reduced pressure can be at an intermediate pressure that is higher than the suction pressure but lower than the discharge pressure of the compressor 10. As a result, the working fluid discharged from the first expander 16 can be in a liquid form, a gaseous form, or a combination thereof. The working fluid discharged from the first expander 16 flows to the evaporator 18 and absorbs heat from a second process fluid (e.g., water, air, etc.), heating the working fluid, and converts the working fluid to a gaseous or a mostly gaseous form. The gaseous working fluid then returns to the compressor 10 via the refrigerant line 26.
A second portion of the cooled working fluid flows from the condenser 14 to the second expander 16′ via the refrigerant line 21. After passing through the second expander 16′, the portion of the cooled working fluid can flow to the compressor 10 via the refrigerant lines 28 and 30. This portion can be fed into the compressor 10 at an intermediate pressure fluid port 12C to be injected into a compression chamber of the compressor 10. The above-described process continues while the refrigerant circuit 1 is operating, for example, in a cooling mode (e.g., while the compressor 10 is in operation).
In an embodiment, the intermediate pressure fluid port 12C can be configured to be an outlet port, with the refrigerant lines 28, 21 and the second expander 16′ disconnected, for example, by removal or fluid control device(s), such as one or more flow control valves. Alternatively, the second expander 16′ may be closed. Accordingly, the second portion of the cooled working fluid flows from the condenser 14 will flow from the condenser 14 to the first expander 16, like the first portion. The intermediate pressure fluid port 12C is configured to discharge a working fluid at an intermediate pressure to the refrigerant lines 30, 29. The working fluid discharged from the intermediate pressure fluid outlet 12C combines with the working fluid in the refrigerant line 26, to be fed into the compressor 10 from the suction inlet 12A. By discharging a portion of the working fluid in the compressor 10 at the intermediate pressure, the compression capacity of the compressor 10 can be controlled, conserving energy consumption of the compressor 10. The intermediate pressure fluid port 12C, functioning as an inlet port and/or an outlet port, can be collectively referred to as a communication port 12C.
It is appreciated that the communication port 12C can be configured as an inlet or outlet port by reconfiguring the refrigerant line(s) connected to the compressor 100 without mechanical alternating the communication port 12C. Accordingly, the description about the “intermediate pressure fluid inlet/outlet port”, “intermediate pressure fluid port”, “communication port”, or “injection port” should be interpreted as a port capable of injecting or discharging. In an embodiment, any fluid described as, for example, injecting into, via, through the communication port, the injection term, process, function, action, or the like, should be interpreted as the fluid being capable of entering or exiting the communication port, depending on external configurations.
The illustrated compressor 100 is a single-stage scroll compressor. More specifically, the illustrated compressor 100 is a single-stage vertical scroll compressor. It is to be appreciated that the principles described in this Specification are not intended to be limited to single-stage scroll compressors and that they can be applied to multi-stage scroll compressors having two or more compression stages. Embodiments described herein with respect to a vertical compressor with a vertical or a near vertical crankshaft (e.g., crankshaft 114). However, it is to be appreciated that features described herein may also be applied to compressors having a crankshaft at a different orientation (e.g., a horizontal compressor).
The compressor 100 includes a suction inlet 112A and a discharge outlet 106. The suction inlet 112A generally protrudes out from the compressor housing to accept a conduit (e.g., refrigerant line 26 in
The compressor 100 includes an orbiting scroll member 108 and a non-orbiting scroll member 110. The non-orbiting scroll member 110 can alternatively be referred to as, for example, a stationary scroll, a fixed scroll, or the like. The non-orbiting scroll member 110 and the orbiting scroll member 108 are in intermeshing arrangement. In some embodiments, the non-orbiting scroll member 110 and the orbiting scroll member 108 may be held in an intermeshing arrangement by an Oldham coupling 112. Each of the orbiting scroll member 108 and the non-orbiting scroll member 110 includes a respective wrap 108A, 110B protruding from a respective baseplate 108B, 110B. In some embodiments, a tip seal 110A, 110B can be disposed respectively on a distal end of each of the wraps 108A, 110A to seal between compression pockets on adjacent sides of each wrap 108A, 108A. In some embodiments, the orbiting scroll member 108 and/or the non-orbiting scroll member 110 can seal against an opposing surface without a discrete tip seal. For example, a feature protruding from a distal end of each of wraps of scroll members can be formed with the same material of the wraps. The feature protruding from the distal end can seal between compression pockets on adjacent sides of each wrap.
The compressor 100 includes the driveshaft 114. The driveshaft 114 can alternatively be referred to as a crankshaft. The driveshaft 114 is rotated by, for example, an electric motor 116. The electric motor 116 can generally include a stator 118 and a rotor 120. In an embodiment, the driveshaft 114 is affixed to the rotor 120 such that the driveshaft 114 rotates with the rotation of the rotor 120. The electric motor 116, stator 118, and rotor 120 operate according to generally known principles. The driveshaft 114 can, for example, be fixed to the rotor 120 via an interference fit or the like. In another embodiment, the driveshaft 114 may be connected to and rotated by an external electric motor, an internal combustion engine (e.g., a diesel engine or a gasoline engine), or the like. It is appreciated that in such embodiments the electric motor 116, stator 118, and rotor 120 would not be present within the housing 102 of the compressor 100.
The orbiting scroll member 108 is affixed to the end of the drive shaft 114. The driveshaft 114 rotates continuously during compressor operation causing the orbiting scroll member 108 to orbit relative to the non-orbiting scroll member 110 of the compressor 100. The orbiting motion intermeshes the orbiting scroll member 108 and the non-orbiting scroll member 110 to form a plurality of compression pockets that are separated by a wrap 108A or 110A and its tip seal 108C or 110C of the orbiting scroll member 108 or the non-orbiting member 110. It is appreciated that the compression pockets are enclosed pockets containing working fluid. The compression pockets are disposed between and enclosed by the orbiting scroll member 108 and the non-orbiting scroll members 110. It is further appreciated that compression pockets are a number of volumes being compressed within the compression chamber 140. The compression chamber 140 occupies a volume between the orbiting and the non-orbiting scroll members 108, 110 fluidly connected to a suction inlet 112A and the discharge outlet 106 of the compressor 100. In an embodiment, the compression chamber 140 includes a suction intake as further described below.
The compressor 100 includes an intermediate pressure fluid port 122. The intermediate pressure fluid port 122 is disposed in the upper portion 102A of the housing 102. The intermediate pressure fluid port 122 is configured to be fluidly connected to an intermediate pressure fluid source, such as an economizer and/or an expander (e.g., the expander 16′). In an embodiment, the intermediate pressure fluid port 122, the suction inlet 112A and the discharge outlet 106 can be tubular machined connections or ports that are welded to the housing 102. In an embodiment, the housing 102, the intermediate pressure fluid port 122, the suction inlet 112A and the discharge outlet 106 can be a single piece, unitary construction. For example, an economizer can be included in the refrigerant circuit 1 and configured to exchange thermal energy between refrigerant lines 28 and 22.
The intermediate pressure fluid port 122 is in fluid communication with an intermediate pressure chamber 124 and configured to communicate (e.g., supply or discharge) intermediate pressure working fluid with the intermediate pressure chamber 124. The intermediate pressure chamber 124 is fluidly connected to the compression chamber 140 via a communication port 126. It is appreciated that the communication port can be referred to as an injection port 126 when the injection port 126 is configured to inject or supply working fluid at an intermediate pressure into the compressor 100. In an embodiment, more than one communication ports can connect the intermediate pressure chamber 124 with the compression chamber 140.
In the illustrated embodiment, the communication port 126 is formed in the non-orbiting scroll member 110 of the compressor 100. Working fluid that has been compressed in the compression chamber 140 is provided from the compressor 100 via the discharge outlet 106. The compressed working fluid (e.g., at a discharge pressure) is then provided to the condenser (e.g., condenser 14 via refrigerant line 20 in
A discharge seal 132 (e.g., a gasket, O-ring, face seal, or the like) and an intermediate seal 130 (e.g., a gasket, O-ring, face seal, or the like) can function to isolate the intermediate pressure chamber 124 from the discharge outlet 106 (e.g., working fluid at a discharge pressure) and a suction chamber 134 (e.g., working fluid at a suction pressure). The discharge seal 132 sealingly engages the upper portion 102A of the housing 102 and the non-orbiting scroll member 110. The intermediate seal 130 sealingly engages the intermediate portion 102B of the housing 102 and the non-orbiting scroll member 110.
In operation, the compressor 100 can communicate (e.g., receive or supply) working fluid at an intermediate pressure via the intermediate pressure fluid port 122. In an embodiment, the intermediate pressure fluid port 122 supplies the working fluid at or about the intermediate pressure to the compression chamber 140 via the injection port 126, where the working fluid is compressed and ultimately discharged via the discharge outlet 106. In another embodiment, the intermediate pressure fluid port 122 receives the working fluid at or about the intermediate pressure from the compression chamber 140 via the communication port 126. The working fluid at the intermediate pressure is supplied, for example, via refrigerant line 29, back to the suction inlet 112A. In the illustrated embodiment, the refrigerant line 29 is external to the compressor 100 (e.g., see
In an embodiment, to ensure that working fluid is flowing into the compression chamber 140 via the injection port 126, and not outward, the working fluid at the injection port 126 (e.g., the intermediate pressure fluid) may generally have a higher pressure than the pressure of the working fluid in the compression chamber 140 at the location of the injection port 126. In an embodiment, because pressure of the compression chamber 140 is cyclic in a scroll compressor, the pressure of the compression chamber 140 at the location of the injection port 126 may briefly be less than the pressure of the working fluid at the injection port 126. However, the intermediate pressure chamber 124 may reduce an impact of any pressure wave that could flow backwards from the normal flow direction. In an embodiment, a one-way valve (not shown, e.g., a check valve) could be included to ensure that working fluid cannot flow backwards from the normal flow direction. The specific location of the injection port 126 with respect to the compression process can be varied.
In an embodiment, the location of the communication port 126 can be selected so that the pressure in the compression chamber 140 is between the suction pressure and the discharge pressure. The communication port 126 can be bored or otherwise drilled or formed in the non-orbiting scroll member 110 of the compressor 100. In an embodiment, the non-orbiting scroll member 110 can be cast or otherwise manufactured to include the communication port 126. A communication port outlet 126A connects the communication port 126 to the compression chamber 140. In an embodiment, the communication port 126 can be bored or otherwise drilled or formed in the orbiting scroll member 108 of the compressor 100.
As discussed above, the driveshaft 114 is affixed to the orbiting scroll member 108 and rotates to drive and orbit the orbiting scroll member 108. As the driveshaft 114 rotates, the orbiting scroll member 108 orbits relative the non-orbiting scroll member 110. The relative rotational position of the driveshaft 114 corresponds to the relative orbital position of the orbiting scroll member 108 relative to the non-orbiting scroll member 110. This relative rotational position of the crankshaft 114 can also be referred to as the crank angle. The corresponding orbital position of the orbiting scroll member 108 can be an orbital position. Crank angle can be the amount of rotation (e.g., X degrees or X°) of the crankshaft 114 from a reference rotational position (e.g., a starting rotational position, or 0°). The orbital position of the orbiting scroll member 108 is defined by the corresponding crank angle. For example, the orbiting scroll member 108 can have a starting position at or about 0° crank angle. The orbital position of orbiting scroll member 108 will be 0°. “About” a certain degree (e.g., about 180°) can include a range above or below the certain degree (e.g., 180°) due to variants from manufacturing variations or tolerances, from normal wear and tear during operation, or the like.
In the illustrated embodiment of
The compression chamber 340 includes the suction intake 320 at an entrance of the compression chamber 340 accepting working fluid at a suction pressure. The suction intake 320 fluidly connects to a suction inlet (not shown) similar to the suction inlet 112A of
A tip seal 308C is disposed on a distal end of the wrap 308A of the orbiting scroll member. The tip seal 308C can be the tip seal 110C in
As shown in
Sharing of the communication port between adjacent compression pockets improves an asymmetric scroll compressor by increasing mass flow and/or increasing efficiency. In some embodiments, the shared communication port can be designed to optimize the performance of the compressor for its intended use (e.g., increased efficiency, increased mass flow, etc.). The communication port can be configured to communicate with the adjacent compression pockets while in a similar pressure range (e.g., pressure of first pocket in the first orbital position is at or about the same pressure as the second pocket ion the second orbital position). At or about the same pressure can be a range of pressure allowing the shared communication port to inject or discharge the intermediate fluid, while still improving the mass flow and/or efficiency of the compressor. A working fluid at the intermediate pressure can be injected or discharged through the shared communication port. By controlling a location of the shared injection port relative to the porting envelop, the designed mass flow into each of the two adjacent compression pockets can be controlled or adjusted. For example, the shared injection port can be configured to be centered biased to one of the two adjacent compression pockets for injecting more into the one compression pocket. In some embodiments, experimental data shows that a shared communication port within a porting envelope can improve compressor efficiency by 2%, which is a significant improvement in the technical field of scroll compressors. In the illustrated example of
As shown in
A communication cycle can correspond to injection into, or communicate with, a first compression pocket (e.g., compression pocket 361, as illustrated in
In another embodiment, one or more supporting structures can be disposed over the injection port outlets 390A-E. The supporting structures can be, for example but not limited to, stripe(s) of materials disposed over the injection port outlet with limited obstruction to airflow through the communication port. The supporting structure can be constructed from, for example but not limited to, the same material of the scroll member milled into or soldered over the communication port. The supporting structures are configured to be in contact with the tip seals and provide support to the tip seal in operation. The tip seal can glide over the supporting structures and have less wear and tear from cutting against large or sharp edges created by an open injection port and extending the lifespan of the tip seal. In some embodiments, the supporting structure can be configured to have, for example but not limited to, other shapes and structures to provide the function of supporting tip seal gliding over the communication port and reducing wear and tear on the tip seal.
In an embodiment, the compressors 500A-500E can be or include similar components with the compressor 10, 100, and 300 as show and described in
The injection port 126 and the injection port outlet 126A, 390 can be designed to minimize a pressure drop of the working fluid having an intermediate pressure. For example, an outlet diameter, an outlet shape, and combinations thereof can be controlled to provide the working fluid with a desired flowrate, overall efficiency, and the like.
In the illustrated examples of
At a method step 610, an asymmetric scroll compressor rotates a driveshaft to orbit an orbiting scroll member affixed to the driveshaft from a first orbital position to a second orbital position to intermesh with a non-orbiting scroll member of the asymmetric scroll compressor, forming a plurality of compression pockets.
At a method step 620, the asymmetric scroll compressor receives the working fluid at a suction pressure from a suction intake disposed between the orbiting scroll member and the non-orbiting scroll member.
At a method step 630, the wraps enclose the working fluid in the suction intake to obtain a first enclosed pocket of the plurality of enclosed pocket.
At a method step 640, the asymmetric scroll compressor communicates with the working fluid at an intermediate pressure from a communication port. For example, the communication port can be fluidly connected to an economizer to receive working fluid at an intermediate pressure.
At a method step 650, the asymmetric scroll compressor, in the first orbital position, communicates with the first enclosed pocket of the plurality of compression pockets via the communication port.
At a method step 660, the asymmetric scroll compressor, in the second orbital position, communicates with a second enclosed pocket of the plurality of compression pockets via the communication port.
At a method step 670, the asymmetric scroll compressor discharges the fluid at a discharge pressure through a discharge outlet.
Aspects. It is noted that any of aspects 1-6 can be combined with any one of aspects 7-12, can be combined with any one of aspect of 13-20.
Aspect 1. An asymmetric scroll compressor comprising: a compressor housing; an orbiting scroll member and a non-orbiting scroll member disposed within the compressor housing, the orbiting scroll member and the non-orbiting scroll member each includes a baseplate and a wrap extending from the baseplate, the orbiting scroll member and the non-orbiting scroll member intermeshed to form a plurality of compression pockets; a driveshaft affixed to the orbiting scroll member and configured to orbit the orbiting scroll member from a first orbital position to a second orbital position; a communication port disposed on the baseplate of one of the orbiting scroll member and the non-orbiting scroll such that: in the first orbital position, the communication port communicates with a first enclosed pocket of the plurality of compression pockets, and in the second orbital position, the communication port communicates with a second enclosed pocket of the plurality of compression pockets.
Aspect 2. The asymmetric scroll compressor of aspect 1, wherein the orbiting scroll member has an intermediate orbital position between the first orbital position and the second orbital position, and during the intermediate orbital position, the communication port communicates with both the first enclosed pocket and the second enclosed pocket.
Aspect 3. The asymmetric scroll compressor of any of the aspects 1-2, wherein the first enclosed pocket and the second enclosed pocket are adjacent in a radial direction and separated by one of the wraps.
Aspect 4. The asymmetric scroll compressor of any of the aspects 1-3, wherein the first enclosed pocket and the second enclosed pocket are at or about a same pressure between the first orbital position and the second orbital position.
Aspect 5. The asymmetric scroll compressor of any of the aspects 1-4, further comprises a porous structure disposed in the communication port, the communication port configured to transfer fluid through the porous structure, and the porous structure configured to mitigate wear on a tip seal disposed on one of the wraps.
Aspect 6. The asymmetric scroll compressor of any of the aspects 1-5, wherein the communication port is disposed within the baseplate of the non-orbiting scroll member.
Aspect 7. A method of communicating working fluid at an intermediate pressure with an asymmetric scroll compressor, comprising: orbiting an orbiting scroll member affixed to a driveshaft from a first orbital position to a second orbital position to intermesh with a non-orbiting scroll member of the asymmetric scroll compressor, forming a plurality of compression pockets; receiving the working fluid at a suction pressure from a suction intake disposed between the orbiting scroll member and the non-orbiting scroll member; enclosing the working fluid in the suction intake to obtain a first enclosed pocket of the plurality of enclosed pocket; communicating the working fluid at an intermediate pressure from a communication port such that: in the first orbital position, communicating with the first enclosed pocket of the plurality of compression pockets via the communication port, and in the second orbital position, communicating with a second enclosed pocket of the plurality of compression pockets via the communication port; and discharging the working fluid at a discharge pressure through a discharge outlet.
Aspect 8. The method of aspect 7, wherein communicating with both the first enclosed pocket and the second enclosed pocket via the communication port in an intermediate orbital position, the intermediate orbital position being between the first orbital position and the second orbital positon.
Aspect 9. The method of any one of the aspects 7-8, wherein the orbiting scroll member and the non-orbiting scroll member each includes a baseplate and a wrap extending from the baseplate, and the first enclosed pocket and the second enclosed pocket are adjacent in a radial direction and separated by one of the wraps.
Aspect 10. The method of any one of the aspects 7-9, further comprising: maintaining the first enclosed pocket and the second enclosed pocket at or about a same pressure at the intermediate orbital position.
Aspect 11. The method of any one of the aspects 7-10, further comprising: orbiting the orbital scroll member from a suction orbital position to the first orbital position to enclose the working fluid in the suction intake.
Aspect 12. A refrigerant circuit, comprising: a compressor, an expander, a condenser, and an evaporator fluidly connected, wherein the compressor includes: a compressor housing; an orbiting scroll member and a non-orbiting scroll member disposed within the compressor housing, the orbiting scroll member and the non-orbiting scroll member each includes a baseplate and a wrap extending from the baseplate, the orbiting scroll member and the non-orbiting scroll member intermeshed to form a plurality of compression pockets; a driveshaft affixed to the orbiting scroll member configured to orbit the orbiting scroll member from a first orbital position to a second orbital position; a communication port disposed on the baseplate of one of the orbiting scroll member and the non-orbiting scroll such that: in the first orbital position, the communication port communicates with a first enclosed pocket of the plurality of compression pockets, and in the second orbital position, the communication port communicates with a second enclosed pocket of the plurality of compression pockets.
Aspect 13. The refrigerant circuit of aspect 12, wherein the orbiting scroll member has an intermediate orbital position between the first orbital position and the second orbital position, and during the intermediate orbital position, the communication port communicates with both the first enclosed pocket and the second enclosed pocket.
Aspect 14. The refrigerant circuit of any one of the aspects 12-13, wherein the first enclosed pocket and the second enclosed pocket are adjacent in a radial direction and are separated by one of the wraps.
Aspect 15. The refrigerant circuit of any one of the aspects 12-14, wherein the first enclosed pocket and the second enclosed pocket are at or about a same pressure during between the first orbital position and the second orbital position.
Aspect 16. The refrigerant circuit of any one of the aspects 12-15, wherein a porous structure disposed in the communication port, the communication port configured to transfer fluid through the porous structure, and the porous structure configured to mitigate wear on a tip seal disposed on one of the wraps.
Aspect 17. The refrigerant circuit of any one of the aspects 12-16, wherein the communication port is disposed within the baseplate of the non-orbiting scroll member.
Aspect 18. The refrigerant circuit of any one of the aspects 12-17, wherein the compressor housing includes an intermediate pressure fluid port, the intermediate pressure fluid port is configured to receive working fluid from an intermediate pressure fluid source, the communication port is configured to receive the working fluid at an intermediate pressure and inject the working fluid into the first enclosed pocket and the second enclosed pocket.
Aspect 19. The refrigerant circuit of any one of the aspects 12-18, wherein the compressor housing includes an intermediate pressure fluid port, the intermediate pressure fluid port is configured to discharge working fluid from both the first enclosed pocket and the second enclosed pocket, the communication port is configured to discharge the working fluid at an intermediate pressure.
Aspect 20. The refrigerant circuit of any one of the aspects 12-19, wherein the communication port is configured to discharge the working fluid at the intermediate pressure to a suction inlet disposed on the housing.
Aspect 21. The refrigerant circuit of any one of the aspects 12-20, wherein the communication port is configured to discharge the working fluid at the intermediate pressure to the condenser.
The terminology used in this Specification is intended to describe particular embodiments and is not intended to be limiting. The terms “a,” “an,” and “the” include the plural forms as well, unless clearly indicated otherwise. The terms “comprises” and/or “comprising,” when used in this Specification, specify the presence of the stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, and/or components.
With regard to the preceding description, it is to be understood that changes may be made in detail, especially in matters of the construction materials employed and the shape, size, and arrangement of parts without departing from the scope of the present disclosure. This Specification and the embodiments described are exemplary only, with the true scope and spirit of the disclosure being indicated by the claims that follow.
Mlsna, Eric S., Ziolkowski, Jr., Joseph E.
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